DE1958674B2 - Flat gas discharge display device for the color representation of electrical signals and method for the production of this device - Google Patents

Description

45

The invention relates to a planar gas discharge display device for the colored representation of electrical signals through individual luminous dots, the two parallel ones that delimit the gas discharge space Glass plates and in between two spaced opposite and transverse to each other, contains ladder systems each consisting of several parallel conductors and processes for production this device.

From the German patent specification 11 77 255 is already a gas discharge display device with non-contact crossing electrical lines is known. There are lighting effects at the crossing points of the electrical conductors located in different levels selectively triggerable. In this known display device, the gap forms an electrical one Gas discharge chamber, one main side of which has a first, essentially transparent, non-conductive Panel wall and its other main side a second, essentially transparent, non-conductive panel- « wall forms. On the first panel wall with the acquaintance a first number of essentially arranged transparent electrical conductors, which are at least partially in the discharge chamber and on the second panel wall a second number of ladders are arranged, which also partially lie in the discharge chamber. The second number of conductors are orthogonal to the first number arranged by ladders.

French patent specification 15 22 257 also discloses a gas discharge color display device become known, are provided in the individual gas discharge cells, depending on the desired Display can contain different phosphors.

These known display devices have the disadvantage of annoying metallic deposits Conductor substance on other conductors in the gas discharge chamber.

Bitzer and Slot tow have in their release "The Plasma Display Panel - A Digitally Addressable Display with Inherent Memory" in the "Proceedings of the Fall Joint Computer Conference" Volume 29, 1966, the mode of operation of the plasma cells in Connection with so-called wall charges treated theoretically.

A device with gaseous or plasma display devices is in the journal "Electronics", Vol 41, Issue 15, page 39, described.

This known display device is a three-layer glass sandwich with a central layer containing rows of holes. These holes are filled with an ionizable gas. The outer layers are transparent. The electrodes or conductors are Lined up orthogonally to one another and each of the holes overlap. According to the mentioned publication a current is fed to the gas via the said conductors, so that a plasma is formed and thus the ignition process is initiated. Each cell provides a so-called wall tension effect with storage effect, so that the known device either as Anzcigcsyslern or as a storage system or in both forms can be used.

It is also known that fluorescent color representations are useful in enhancing the reproduction performance of Display systems are very useful in providing more effective information encryption and generally provide more contrast for human distinction. They are already different Ways to provide the gas discharge display devices with color capability just mentioned have become known. So it is B. known that conventional methods such. B. by knocking down can introduce phosphor by means of sedimentation in each hole of the middle layer of the device.

The deposition method using sedimentation to deposit phosphor is generally at Applications, as they represent cathode ray tube screens, satisfactory because there is a Aluminum substrate prevents the formation of pinholes or unevenness in the fluorescent layer, which in other cases makes a very difficult problem. The method mentioned is sufficient in those as well Cases where the exact thickness of the phosphor layers is not particularly important.

However, the deposition method by means of sedimentation is largely unusable and costly, if it is to be used in the manufacture of plasma display devices. this is the Complexity of the precipitation, the bad effect due to the not precisely controllable luminous

fabric thickness and the general inability to provide convenient means for selective application attributable to different phosphors on different electrodes.

There are also gas discharge display devices with non-contact crossing electrical lines known, at the intersections of which lighting effects can be selectively triggered. There is also a gas discharge color display known, in which individual gas discharge cells are provided, depending on the desired Display can contain different phosphors. But these devices have the disadvantage of disturbing precipitation of metallic conductor substance on other conductors in the gas discharge chamber.

The object on which the invention is based is to remedy those discussed above Difficulties and in the creation of an improved planar gas discharge display device and in the provision of an improved method of making this device in which the interfering Precipitation of metallic conductor substance on other conductors in the gas discharge chamber does not occur can.

For a flat gas discharge display device for the colored representation of electrical signals through individual light points, the two parallel glass plates delimiting the gas discharge space and in between two at a distance opposite one another and running transversely to one another, each made up of several contains parallel conductors existing conductor systems, then the invention is that the ladder a wear a thin, uniform layer of phosphor about 5μ thick.

The thin phosphor layer is advantageously applied by cataphoresis. Different leaders the phosphor layers can have different colors.

A special method for producing the planar gas discharge display device results from the subclaims.

This process proves to be quite cheap, since it involves applying selected phosphors to different ones Ladders made possible in a simple but effective manner. Otherwise, this would be achieved with Acquaintances can be costly and time-consuming.

Embodiments of the invention are shown in the drawings and are described below described in more detail.

It shows

1 shows a cross section of the planar gas discharge display device,

2, 3 and 4 show the manufacturing method of the planar gas discharge display device

by cataphoretic deposition of phosphors on the conductors, which are on the walls of the Sitting display device,

Figure 5 is a simplified perspective view of those used in cathaphoretic deposition Anode. e> o

In the planar gas discharge display device according to FIG. 1, a so-called "open Cell gas discharge display device «30 is formed in which the wall charges are on non-conductive Walls in the neighborhood of selected ladder tr, or electrodes, e.g. B. collect the leader groups 32a and 34a. Furthermore, outer glass plates 36 and 38, which contain the main walls of a gas cell 40 are provided.

The gas cell 40 is completed by an insulating wall 42 extending between the walls 36 and 38 extends and the outer ends of the chamber are arranged.

A number of conductors or strips 34a of a group 34 are arranged in parallel on the Inner surface of plate 38 within gas cell 40. Another number of conductors or strips 32a one Group 32 is in parallel association on the inner surface of plate 36 and also within it Gas cell or chamber 40 attached.

As shown in FIG. 1 can be seen, the conductor groups 32 and 34 are mutually orthogonal. As the F i g. 1 further shows, each of the conductors is covered with a thin layer which is a cataphoretically deposited phosphor layer shown in FIG. 1 is denoted by 44. Layer 44 applied to each of the conductors serves several purposes. Once it provides isolation between the conductors and the gas within the cell 40. It also enables the collection of wall charges during the commissioning of the apparatus, and supplies the color capability of the display device 30th

As for the first function of the layers 44, it is known to have internal conductors in the open cell type the gas discharge indicator must be isolated from the gas within the cell. Wouldn't that be the case, would one of the ladder sets refer to the other ladder set? knock down, as is well known is the case with the known vapor deposition technique.

As far as the coloring function of the phosphor is concerned, it is important that the layers 44 are uniform and flat so as to ensure uniform lighting in the event of excitation of the phosphor is.

The gas mixture in the chamber 40 advantageously consists of a mixture of 90% neon and 10% Nitrogen at a pressure of 150 torr. When the gas breakthrough while the plasma cell is operating 30, ultraviolet light is emitted, which causes the luminescence of the phosphor layers 44.

However, it is also possible that a heavier gas than the above mixture can pass through the phosphor can excite molecular bombardment. Furthermore, there is a very thin layer of phosphor (of the order of magnitude 5 microns thick) is highly desirable because it has been found that a thinner layer has less resistance and ages more slowly than a thick layer.

In addition, as already mentioned, the layer 44 must be free of pinholes so that vapor deposition can occur the conductors 32a or 34a is avoided during operation of the display device 30. The cataphoretic applied layers 44 meet all these requirements. A cataphoretically applied The phosphor layer can therefore be precisely controlled in terms of thickness. It is uniform and even and essentially free of pinholes or irregularities.

When commissioned, the display device 30 is selectively an operating voltage of approximately 800 volts the orthogonally arranged conductor groups 32 and 34 supplied. The gas molecules break at the intersection a selected leader or leaders from each of the Groups 32 and 34 through. However, neighboring locations are not ignited or excited at this time, because of the insufficient to breakthrough

leading tension at these points.

In practice, the walls 36 and 38 are separated so that a distance of 0.2 to 0.24 millimeters is created between the groups of conductors 32 and 34. The field strength in the exemplary embodiment is therefore approximately 10 ⁴ volts / cm. Furthermore, the conductors 32 and 34 even in the working area 31 of the display device have a width of approximately 0.24 mm with a gap between the conductors of approximately 0.24 mm, which results in a relatively high resolution. A work area which comprises a single character and up to multiple characters is achieved in a simple manner. The area of a single character can be approximately 16.13 mm ² .

On the basis of FIG. 2 is a preferred manufacturing method for the display device 30 below described. At the beginning a suitable transparent material, which withstands a phosphor suspension, is z. B. tin oxide, deposited on one of the glass plates 36 and 38 to form the conductive groups 32 and 34 to build. The front panel of the display device 30, e.g. B. the plate 36, preferably has a pleated inner surface or surface on the work area. This surface property can have mirror quality. The conductor group 32 is applied to this inner surface.

A solution of tin chloride and methyl alcohol, mixed with antimony trichloride, is made up. The solution is chemically applied to the glass plates 36 and 38 by initially heating the plates to about 425 ° C. and spraying them through a mask in the presence of a water vapor atmosphere. The chemical precipitation of tin oxide is achieved by a chemical reaction of the steam. In this way, the conductor groups 32 and 34 are formed. The thickness of the conductors is preferably about 3000 Å, and the width and the neighboring spacing is advantageously about 0.24 mm each. According to FIG. 2 is one of the plates, e.g. B. the plate 38 with the conductors 34a is placed in a suitable container 50. In the container there is a phosphor suspension 52. This suspension can, for. B. be a zinc-cadmium-sulfide-silver activated phosphor. The suspension is prepared by adding decanted fine fluorescent article with about 1 to 2 microns in diameter to an ethyl alcohol solvent containing 5% by volume water and 10 ^-4 moles per liter of thorium nitrate.

The suspension is made by adding ingredients and stirring for 30 minutes, further formed by grinding and by shaking or by vibration. With the plate 38 in the suspension 52, is also the anode part 60 (Fig. 5) introduced there. Of the The anode part 60 consists of the conductors 62 which physically follow the conductors 34a of the group 34 Shape, size and spacing are very similar. This allows for a uniform field between the Conductors (anode and cathode) during the cataphoretic precipitation, without field scattering that arises from direct migration of the fluorescent particles from the suspension to the conductors 34. That’s a ensures a uniform, even coating that is free from pinholes.

With the negative terminal of a suitable direct current source, selected conductors from group 34, z. B. 34/4 and 34Ö connected. The anode part 60 is on connected to the positive source of the DC power source. The tissue layers 44 are on top of these Cataphoretically deposited over electrodes 34,4 and 34β to a desired thickness. So can z. B. when using the suspension described above and at a field strength of about 50 volts per cm a 4 micron thick phosphor layer 44 was formed on conductors 34/4 and 34 [beta] in about 1.5 minutes will.

It should be noted that conductors 34C and 34D of group 34 are not connected to the DC power source and therefore do not take up a layer at this time.

From Figure 3 it can be seen that the plate 38 is now in a suspension 54 is introduced, which may contain a phosphor of a different color which is prepared in the manner described above. The suspension 54 can, for. B. a zinc sulphide silver be activated phosphor. Again, note that unconnected conductors 34C and 34Din Suspension 52 does not take up any layer. Therefore, when these conductors 34C and 34D are in suspension 54 are introduced and connected to the power source, they receive a phosphor of a different color. In In reality, the plates 36 and 38 will have many more conductors than is shown in FIGS. 1 and 2 and 3 with the four ladders is shown. It should be noted that the problem of using different colored phosphors on many small conductors with the known methods is extremely difficult, whereas this is extremely difficult with of the present invention is a fairly simple matter. Indeed, of course it could be that if all of the conductors 34a on plate 38 were covered with the same color phosphor, only this by simply connecting all conductors to the DC power source when those conductors are in suspension 52 are to be completed. It should also be noted that a third or further other phosphor layers on the ladder in the same way as in FIG. 2 and 3 can be applied. In this case a Plate 38 is made with many conductors 34a, which alternate with green, blue and red phosphor layers 44 are covered. In Fig. 4, the plate 36 is in a suspension 58, which in turn is in a container 70 is located. The conductors comprising group 32 on this plate are received cataphoretically deposited phosphor layers in the same way as already described above. In this case, an anode is used which is similar to part 60 and which is physically similar to conductor group 32 very much like.

When the leader groups 32 and 34 are on calaphoretic As their phosphor layers 44 have received, the plates 36 and 38 will be with their inner Areas placed in close proximity. Thereby the chamber or the gas cell with the spaces in between

μ 72 and 74 formed. As mentioned earlier, the Conductor groups 32 and 34 are preferably separated by about 0.24 mm at this point. The spacers are fastened and the wall 42 is formed to complete the chamber and, by using

wi formation of an epoxy resin or the like. As a sealant complete. The chamber 40 is then evacuated. This happens e.g. B. by drilling a hole in the Panel wall 36 or 38 and by peeling it off until the vacuum is established. After evacuation, the the chamber a suitable gas, e.g. B. a mixture of 90% neon and 10% nitrogen filled in to complete the fabrication of the Pancclcs30.

1 sheet of drawings

Claims (5)

Patent claims: 1. Flat gas discharge display device for displaying electrical signals in color through individual light points, the two parallel glass plates delimiting the gas discharge space and in between two at a distance opposite one another and running transversely to one another, respectively contains ladder systems consisting of several parallel ladders, characterized in that, that the conductors (32, 34) carry a thin, uniform fluorescent material (44) about 5 μ thick. 2. Flat gas discharge display device according to claim 1, characterized in that the thin phosphor layer (44) is applied by cataphoresis 3. Flat gas discharge display device according to claims 1 to 2, characterized characterized in that different conductors (32, 34) carry phosphor layers (44) of different colors. 4. A method for producing the planar gas discharge display device according to the claims 1 to 3, characterized in that a first suspension of fluorescent particles is predetermined Color is created that in this suspension one of the glass plates with the applied on it Ladder system is arranged and that at least partially some ladder of the ladder system through cataphoretic deposition of phosphor particles from the first suspension with phosphor be coated. 5. The method according to claim 4, characterized in that a second suspension of luminous J5 fabric particles of another preselected color is created, that the glass plate with the conductor system is introduced into this second suspension and that at least partially some of the remaining, uncoated conductors by cataphoretic w precipitation of phosphor particles from the second suspension are coated.